Dental implant system

ABSTRACT

The dental implant system includes implants having integral abutments therewith for the removable or fixed attachment of plural or single prosthetic teeth, as appropriate. The system for removable dental prostheses includes a metal housing permanently installed in the removable prosthesis, and a rubber retentive insert installed in the housing. The insert is removably installed over the abutment of the implant to secure the dental prosthesis thereto. The system includes transfer copings for transferring an impression to the lab for manufacture of the prosthesis, and lab processing copings and analogs for handling and forming the prosthesis during manufacture. The system may be assembled as a kit having some or all of the above components.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a division of Ser. No. 12/461,954, filed on Aug. 28,2009, now pending, which application claims the benefit of U.S.Provisional Patent Application Ser. No. 61/111,941, filed on Nov. 6,2008, and Ser. No. 61/215,954, filed on May 12, 2009.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to the field of dentistry, andparticularly to a dental implant system for mini dental implants.

2. Description of the Related Art

Traditional removable partial dentures, i.e., the replacement of arelatively few missing teeth with prosthetic teeth, have been secured inthe mouth by means of relatively rigid wire or other metal attachmentsextending from the dentures and removably attached to adjacent teeth.Removable full dentures, which replace all or nearly all of themandibular or maxillary teeth, have traditionally been adhesivelysecured in the mouth. Single prosthetic teeth, i.e., crowns,traditionally require at least some portion of the natural tooth forfixed attachment thereto.

More recently, various implants have been developed that anchor directlyinto the mandibular or maxillary bone structure, with the prosthetictooth or teeth being permanently or removably attached to the protrudingabutment of the implant. Most such implants are relatively large and arenot suitable for the medically, financially, or anatomically compromisedpatient. The installation of such larger implants is a multi-stepprocedure, with the patient initially receiving oral surgery to open thegingival tissue and expose the underlying bone structure, whereupon thebone is drilled and tapped for the implant and the implant is installed.The patient must then wait for the soft tissue to heal and for aconsiderable period of time for the bone to grow around the implant andanchor the implant firmly in place. A subsequent visit is required afterhealing for the dentist to make an impression of the area in which thedental prosthesis is to be installed. The impression is then sent out toa dental laboratory for the manufacture of the dental prosthesis.Finally, the completed prosthetic tooth or other dental prosthesis isfit into place during still another visit to the dentist.

Even more recently, so-called “mini-implants” or mini dental implantshave been developed. These relatively small implants do not requirespecific lying open of the gingival tissue or the drilling of relativelylarge holes in the bone structure. Rather, the small hole for theminiature implant can be drilled directly through the gingival tissueand into the underlying bone. The mini-implant can be placed orinstalled in most all compromised patients. This is a minimally invasiveapproach and even the medically compromised patient, and particularlythe edentulous patient, can withstand the placement procedure due to thestability of the mini-implant and prosthesis. In cases where theprocedure is for the reinstallation of a retrofit denture or prosthesis,the mini-implant(s) can be installed and the prosthesis installedthereon in a single visit to the dentist. In the case of a new denture,the mini-implant(s) are placed during one visit, and the impression forthe prosthetic tooth or teeth is made during the same visit. The patientreturns in only a few days later for the final fitting of the newprosthesis after it has been manufactured in the dental laboratory. Ascan be seen, the use of mini-implants greatly reduces the time andeffort, and thus the cost, of implant placement, as well as greatlyreducing the trauma to the patient.

However, many if not most such implants are of multiple piececonstruction, with a threaded implant portion having an upper endfitting generally flush with the exposed gingival surface and anabutment portion that attaches to the implant in some manner. Moreover,it has been recognized that some cushioning is desired between theremovable dental prosthesis and the underlying abutment, implant, andbone structure, thus relieving the stress otherwise imposed upon theimplant. This has been accomplished in the past by means of a smallO-ring installed between the dental prosthesis and the abutment, whichhas proven to be less than satisfactory. In practice, these systems tendto collect food residue between the retainer cap and the spherical headof the abutment, thus preventing the ball of the abutment from seatingcompletely and resulting in an unstable and poorly fitting dentalprosthesis.

Another problem that can occur in the placement of conventionalminiature implants is that the impression material if not contained mayflow into the crevice between the gum line and the overlying structure.This can result in some chance that the impression material (orprosthesis material, in the case of a retrofit installation) may belocked around the abutment and its retentive mechanism, within theoverlying interface between the gingival surface and the overlyingprotruding abutment.

Thus, a dental implant system solving the aforementioned problems isdesired.

SUMMARY OF THE INVENTION

The dental implant system comprises implants with integral abutments foruse in securing both removable and fixed dental prostheses in the mouth.The system also includes components installed in the removable or fixedprostheses for securing the prostheses to the abutments of the implants.Various components are also provided for the formation of the prosthesesand for their installation. Some or all of the various components of thepresent system may be combined as a kit, if so desired. A ratchet typeinstrument or tool having a drive socket may be provided for driving theimplants, with the specific drive being configured as required forvarious abutment forms. Separate interfacing components havingcorresponding fittings for mating to the abutment of the implant and thesocket of the instrument may also be provided.

In one embodiment, the system comprises a threaded mini-implant havingan integral abutment. A metal retentive housing includes a rubberretentive insert removably installed therein. The metal housing ispermanently affixed in the dental prosthesis. The rubber insert installsremovably over the abutment of the implant to permit the dentalprosthesis to be removed and reinstalled as desired. A rubber gasket orring is provided at the time of forming the impression or retrofittingan existing dental prosthesis. The gasket or ring is placed about thebase of the abutment to prevent the flow of impression material into thegap between the gingival tissue and the overlying prosthetic retainer.

Another embodiment comprises a mini-implant with an asymmetric abutmentthat generally simulates the contours of a natural tooth. This implantis used for the installation of a fixed dental prosthesis, e.g., asingle artificial tooth, or perhaps a plurality of implants for severalteeth.

Yet another embodiment includes a transfer coping installed on theabutment at the time of forming the impression. The transfer coping iscaptured and becomes an integral component of the impression so that ananalog may be placed for making a model of the structure.

Another embodiment includes a laboratory (lab) processing coping, withthe lab processing coping serving two functions. First, the dentist cantry the coping at the time of placement of the dental mini implant toassure that the finish line, i.e., the boundary between the base of theabutment structure and the overlying dental prosthesis, is sub-gingivalin order to provide a seal between the prosthetic structure and thesurrounding tissue to preclude the entry of food residue therein.Secondly, the laboratory technician can use the lab processing coping tofabricate the prosthetic material in the construction of the fixedprosthesis. An analog and sleeve assembly is also provided for handlingthe impression and for forming the dental prosthesis from theimpression.

These and other features of the present invention will become readilyapparent upon further review of the following specification anddrawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an exploded perspective view of a dental implant andprosthetic attachment assembly in a dental implant system according tothe present invention, showing its various components.

FIG. 2 is an elevation view in section of the installed implant andprosthetic attachment assembly of FIG. 1, illustrating further details.

FIG. 3 is an exploded perspective view of a metal retentive housing andrubber retentive insert in a dental implant system according to thepresent invention, shown with an instrument used for their assembly.

FIG. 4 is an exploded perspective view of an implant adapted for theattachment of a fixed dental prosthesis thereon, and the transfer copingfor forming the prosthesis on the abutment of the implant, in a dentalimplant system according to the present invention.

FIG. 5 is an exploded perspective view of an analog and pin and a sleeveused in the formation of a dental stone model and for receiving the labprocessing coping in a dental implant system according to the presentinvention.

FIG. 6 is an elevation view in section of an installed implant and a labprocessing coping used in the fabrication of a fixed dental prosthesisin a dental implant system according to the present invention.

FIG. 7 is an exploded perspective view of an alternative embodiment ofan implant and abutment in a dental implant system according to thepresent invention, shown with a corresponding transfer coping.

FIG. 8 is an elevation view in section of an installed implant in adental implant system according to the present invention, shown with itscoping and dental prosthesis affixed thereto.

Similar reference characters denote corresponding features consistentlythroughout the attached drawings.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The present invention relates to a dental implant system incorporatingmini dental implants having abutments formed integrally therewith. Thesystem includes implant embodiments for installing both removable andfixed dental prostheses, as well as components for use with transfer andlab processing copings and an analog and pin with a locking feature foruse during the manufacture of the prosthesis. The various components ofeach embodiment may be provided as a kit, if so desired.

FIGS. 1 through 3 of the drawings illustrate the components andexemplary installation of a first embodiment of the dental implantsystem, comprising an assembly wherein the dental prosthesis isremovably secured within the mouth of the user. FIG. 1 of the drawingsprovides a perspective view of a kit 10 for the installation of aremovable prosthesis in the mouth, with FIG. 2 providing an elevationview in section of the completed installation and FIG. 3 illustratingthe assembly of certain components of the system.

The assembly and installation shown in FIGS. 1 through 3 uses aminiature dental implant 12. The implant 12 is a so-called “mini”implant, i.e., having a total length, including the threaded baseportion 14 and abutment portion 16, of about 16 to 23 mm, more or less,with the base 14 and abutment 16 being formed as a single integralcomponent. The base 14 includes helical threads 18 thereon, and tapersto a pointed distal tip 20. The helically threaded base 14 furtherincludes one or more axial grooves 22 therein, with the grooves 22serving to accept bone growth during the healing process to prevent theimplant 12 from rotating within the bone structure and to providegreater anchorage and security for the implant 12. The threaded baseportion 14 is narrow in width, having a diameter of about 2.4 mm, orbetween about 1.8 mm and 2.9 mm.

The opposite end of the base portion 14 includes a sub-gingival collar24 having a conical taper to the helical threads 18 of the base portion14, with the conical taper having a smooth and unthreaded upper portionwith a plurality of very fine “micro-threads” 26 extending about thelower portion to the helical threads 18 of the base portion 14. Therelatively finely cut micro-threads 26 provide a better seal between theimplant 12 and the surrounding bone or tissue structure once the implanthas been installed. As the name implies, the conical sub-gingival collar24 extends somewhat below the gingival tissue G and into the underlyingbone structure B so that the micro-threads 26 engage the outermostcortical bone material, generally as shown in FIG. 2 of the drawings.The top or widest diameter portion of this sub-gingival collar 24 isdescribed as a “finish line,” and resides essentially level with theupper surface of the soft gingival tissue in the removable dentureembodiment of FIGS. 1 and 2.

The abutment 16 has an essentially cylindrical shape and acircumferential groove 28 formed therearound. This groove 28 serves as aseating element and anchor for a resilient elastomeric (rubber, etc.)insert that is removably installed over the abutment 16, as explainedfurther below. The abutment 16 has a head 30 opposite the sub-gingivalcollar 24. The head 30 has a somewhat larger diameter than that of thebalance of the abutment 16. The head 30 is of a non-circularconfiguration, e.g., it includes at least one flat 32 or othernon-circular element (e.g., a notch, etc.) formed in the peripherythereof, as shown in FIG. 1. This provides for the placement of atorsion instrument or adapter over the head 30 of the abutment 16 forturning the implant 12 and advancing it into a hole previously formed inthe bone structure. The relatively small diameter and length of thehelically threaded base portion 14 of the implant 12 allows it to bescrewed into a previously formed unthreaded hole without the need toperform the extra step of threading the hole. The self-tapping helicalthreads 18 enhance the physical security of the implant installation.

A prosthesis-retaining housing 34 is permanently affixed (i.e., cast ormolded in place) within the dental prosthesis P. In the example of FIG.1, the dental prosthesis P1 is shown in broken lines as a section orportion of a removable partial or full denture or the like. The housing34 is embedded in the lower portion or tissue side (internal surface) ofthe prosthesis P1. While a full or partial denture would be the mostcommon installation for a removable prosthesis in the dental implantsystem, it will be seen that the same configuration may be applied tosmaller, individual tooth prostheses, e.g., the single tooth prosthesisP2 of FIG. 2, if so desired.

The housing 34 is preferably formed of thin metal, and has a generallycylindrical configuration with a closed top or cap defining a hollowinterior 36 (shown in FIGS. 2 and 3). The top or cap includes anoutwardly extending circumferential flange 38, serving to prevent thehousing 34 from pulling out of the dental prosthesis P1. An outwardlyprotruding circumferential bead or band 40 extends about the housing 34,the band 40 including at least one break or discontinuity 42 therein.This break or discontinuity 42 provides for the inclusion of material ofthe removable dental prosthesis P1 to flow therein during manufacture ofthe prosthesis, thus precluding rotation of the otherwise circular orcylindrical retaining housing 34 within the prosthesis P1.

Further details of the retaining housing 34 are shown in FIGS. 2 and 3.FIG. 3 particularly illustrates the means for retaining the elastomericinsert therein. The lower edge or base of the generally cylindricalhousing 34 includes an inwardly extending base flange 44 defining ashallow conical shape. The flange 44 serves to retain the inserttherein. The flange 44 includes a plurality of radially disposed slots46 defined therein to permit the insertion of the insert into thehousing 34, with each slot 46 having a stop tab 48 formed from theupwardly bent end of the adjacent flange portion.

The resilient elastomeric insert 50 serves as a connecting elementbetween the housing 34, which is permanently affixed into the prosthesisP1 or P2, and the abutment portion 16 of the implant 12, which ispermanently installed in the mandibular or maxillary bone structure ofthe patient. The insert 50 is of a generally cylindrical configuration.The diameter of the insert 50 closely matches the diameter of thepassage defined by the base flange 44 of the retaining housing 34. Theinsert 50 has a series of axial ribs 52 extending radially from thecylindrical core. The ribs 52 are aligned with and closely fit throughthe slots 46 of the base flange 44 of the housing 34 when the insert 50is installed therein. The diameter defined by the outer reaches of theribs 52 closely matches the internal diameter of the housing 34, toprovide a closer fit between the insert 50 and housing 34 when theinsert 50 is installed therein.

The insert 50 has a cushioning flange 54 extending radially from andcircumferentially about the base of the insert 50. The cushioning flange54 fits below the base flange 44 of the housing when the insert 50 isinstalled therein. The lower ends of the axial ribs 52 and thecushioning flange 54 define gaps 56 therebetween, to allow the baseflange 44 of the housing 34 to fit between the ribs 52 and cushioningflange 54 of the insert 50. The cushioning flange 54 serves as a cushionor shock absorber between the metal retentive housing 34 and theshoulder of the abutment 16 for the removable prosthesis P1 of FIG. 1 orthe single tooth P2 of FIG. 2, and the oral structure of the patientwhen the assembly is completed and installed in the mouth of thepatient.

The resilient elastomeric insert 50 has an abutment receptacle 58 formedconcentrically therein. The receptacle 58 provides for the removableinstallation of the insert 50 (and attached housing 34 and dentalprosthesis P1 or P2) to the abutment 16 of the implant 12. Thereceptacle 58 is configured to closely fit the contours of the abutment16, i.e., having an inwardly formed circumferential rib to fit theabutment groove 28, a circumferential groove formed in the head of thereceptacle 58 to fit the corresponding circumferential flange of thehead 30 of the abutment 16, and an inward conical taper at the mouth ofthe receptacle 58 to fit the conical collar 24 or shoulder of theabutment 16.

The insert 50 is installed within the housing 34 by aligning the ribs 52of the insert 50 with the slots 46 in the base flange 44 of the housing34, and inserting the insert 50 axially into the housing 34. The insert50 is then locked into the housing 34 by twisting or rotating the insert50 within the housing 34 until the ribs 52 are stopped by the stop tabs48 at one edge of each of the slots 46. This captures the ribs 52 of theinsert 50 above the base flange 44 of the housing 34 to prevent theinsert 50 from pulling out of the housing 34. The rotation of the insert50 in the housing 34 also closes or covers the slots 46 of the housing34, thereby precluding entrance of foreign matter into the housing.

The abutment receptacle 58 of the insert 50 includes a non-circularinstrument receptacle 60 in the upper end thereof, i.e., opposite theopening through the cushioning flange 54. This instrument receptacle 60allows the similarly shaped bit 62 of an insert installation instrument64 to be inserted therein. Rotation of the instrument 64 producescorresponding rotation of the insert 50 within the housing 34. Removalof the insert 50 from the housing 34 is accomplished by rotating theinstrument 64, and thus the insert 50, in the opposite direction fromthat used to lock the insert 50 in place within the housing 34, andwithdrawing the insert 50 axially from the housing 34. The processrequires but a few minutes to remove and replace worn inserts 50 in aremovable partial or full dental prosthesis P1, and is easilyaccomplished in the dental office, or even at home by the owner of thedental prosthesis.

Dental prostheses are conventionally formed by molding a pliable orsemi-liquid material (plastic, etc.) in the mouth of the patient inorder to provide a close and precise fit between the oral structure ofthe patient and the dental prosthesis. The insert 50 and housing 34 areinstalled on the previously installed implant 12, and the material flowsor is molded about the housing 34 to become an integral part of theremovable prosthesis, or for a retrofit, an existing removableprosthesis. It will be seen that the semi-liquid characteristics of thematerial used to form the model will allow this material to flow beneaththe conical cushioning flange 54 of the insert 50.

Accordingly, an elastomeric ring 66 is provided to serve as a sealbetween the cushioning flange 54 of the insert 50 and the underlyingoral structure of the patient during the process of making an impressionfor a new prosthesis or retrofitting an existing prosthesis. Theelastomeric ring 66 includes a central passage therein to fit about theabutment 16 of the insert 12, and a conically sloped intermediateportion 68 extending outwardly therefrom to a thin, flat outer sealingflange 70. The intermediate portion 68 closely fits the conical shape ofthe bottom of the cushioning flange 54 of the insert 50, and precludesthe introduction of material between the flange 54 and the underlyingsoft tissue (gum) during the formation of the impression for theprosthesis. Once the impression has been formed and removed from themouth of the patient (along with the housing 34 and insert 50 capturedtherein), the elastomeric ring 66 is removed from the abutment 16 anddiscarded.

FIGS. 4 through 6 illustrate components used in the manufacture andinstallation of one embodiment of a fixed dental prosthesis. Thesecomponents may be provided as a group in the form of a kit, if sodesired. The implant 112 of FIGS. 4 and 6 is similar to the implant 12of FIGS. 1 and 2, and is in fact identical thereto from the finish line,i.e., the widest diameter or upper end of the sub-gingival collar 124down, having a base 114 with helical threads 118 thereon andmicro-threads 126 about the lower portion of the conical sub-gingivalcollar 124, a sharply pointed distal tip 120, and one or more axialgrooves 122 formed along the base 114.

The abutment portion 116 of the implant 112 has a significantlydifferent configuration from the corresponding abutment 16 of theimplant 12 of FIGS. 1 and 2, however. The abutment 116 is shaped orconfigured to conform to the interior shape and configuration of boththe transfer coping 134 shown in FIG. 4, and the lab processing copingillustrated in FIGS. 5 and 6. The abutment 116 has a generally smoothlycurved or rounded upper or distal portion, with a circumferential groove128 formed therein at about one third of the distance from the base tothe tip of the abutment 116. A labial or forwardly oriented flat 132 isprovided for abutments and implants configured for use with frontal(anterior) tooth prostheses.

The transfer coping 134 includes an abutment receptacle 136 definedtherein that is configured to fit closely about the abutment 116. Thetransfer coping 134 has a generally cylindrical external shape and anoutwardly extending circumferential flange 138 at the top of the coping134, and an outwardly protruding circumferential band 140 extendingabout the coping 134. The flange 138 and/or band 140 are preferablynon-circular, i.e., having a flat or other non-circular discontinuityformed thereon or therein in the manner of the flat 32 formed along theside or edge of the head 30 of the abutment 16 of FIG. 1. Adiscontinuity or gap, respectively 138 a and 140 a for the flange 138and band 140, may be provided to serve this function. This prevents theimpression I (shown in broken lines in FIG. 4) from rotating thereon, orthe uninstalled coping 134 from rotating within the impression I. Anoutwardly extending or flaring skirt or flange 144 extendscircumferentially about the base of the transfer coping 134 from the“finish line,” i.e., the juncture between the base of the cylindricalbody of the coping 134 and the skirt or flange 144. This skirt or flange144 serves to expand and hold back the gingival tissue during thefitting of the transfer coping 134, in a manner similar to the use ofpacking cord about a natural tooth that has been prepared for a fixedprosthetic restoration.

The process of forming and installing a single, fixed prosthetic tooth,e.g., the prosthetic tooth P3 of FIGS. 5 and 6, begins with theinstallation of the implant 112 into the jawbone structure of thepatient, generally as described above for the removably installed dentalprosthesis illustrated in FIGS. 1 through 3. A “stone model,” i.e., acasting formed of material that cures into a hard and rigid structure,is formed of the patient's mouth, or more precisely, the stone model isformed to provide an analog of that portion of the patient's mouth inwhich the dental prosthesis is to be installed. The transfer coping 134is placed upon the abutment 116 of the implant 112, and an impression Iis formed over the transfer coping 134. Once the impression I has beenformed, the impression I and the transfer coping 134 are removedtogether from the implant abutment 116. The transfer coping 134 andimpression assembly is placed upon an implant analog pin in the stonemodel in order to send the impression I to a dental lab for manufactureof the fixed dental prosthesis, e.g., the prosthesis P3 of FIGS. 5 and6.

An implant analog and pin 212 and associated components are illustratedin FIG. 5 of the drawings. The analog and pin 212 includes a base or pinportion 214 and an abutment or analog portion 216 extending upwardlytherefrom. The pin or base 214 is devoid of threads, as it is notintended to be installed permanently in the stone model (or any otherstructure, as a permanent installation). However, it does have anon-circular cross section, e.g., longitudinal facets 218, in order toprevent it from rotating within a fixture or sleeve previously installedin the stone model during the manufacture of the prosthetic tooth. Theabutment or analog portion 216 is configured to match precisely theinternal contour and shape of the transfer coping 134 and also the labprocessing coping 150 shown in FIGS. 5 and 6, which internally matchprecisely the external contours of the abutment of the implantpreviously affixed in the patient's mouth.

When the lab receives the assembly that includes the impression I andtransfer coping 134 (FIG. 4) temporarily installed on the analog and pin212 (FIG. 5), the base portion 214 of the analog pin is installed in aholder or sheath 312 (FIG. 5) in the stone model. The sheath 312 alsohas a non-circular cross section, both internally and externally. Theinternal cross section is configured to fit closely about the exteriorof the base or pin portion 214 of the analog and pin 212 in order toprevent the analog and pin 212 from rotating within the sheath 312,while the non-circular exterior of the sheath 312 prevents it fromrotating when installed in the stone model (analog of the oral structureof the patient) for the manufacture of the dental prosthesis. Additionalanti-rotation means may be provided by one or more circumferentiallydiscontinuous bands or rings 340 disposed about the sheath 312. Thebands 340 may have breaks or discontinuities 342 therein to precluderotation of the sheath 312 within the stone die or model.

The analog and pin 212 is retained within the sheath 312 by a distalprotruding tab 220 that extends from the tip of the pin portion 214 andthrough a hole 320 in the tip of the sheath 312. The base or pin portion214 of the analog and pin 212 is installed in the sheath 312 with thetab 220 protruding through the hole 320 in the base of the sheath, and awasher 366 is placed over the tab 220. The tab 220 includes a passage222 therethrough, through which a retaining pin 322 is placed to securethe analog pin 212 within the sheath 312 for the duration of manufactureof the dental prosthesis, e.g., single tooth prosthesis P3; multipleunits would be required for a denture having multiple teeth.

A lab processing coping 150 is provided for the manufacture andpermanent installation of the dental prosthesis P3 thereon. The labprocessing coping 150 is formed as a thin shell and includes an internalcavity or recess 158 a closely matching and mating with the contours andshape of the abutment 216 of the analog pin 212. The internal cavity orrecess 158 a is devoid of any rings or other retaining structure, as itmust be removable from the abutment analog 216 of the analog and pin212. The external shape and contour 158 b closely matches the internalshape and contour of the receptacle 136 of the transfer coping 134. Thispermits the dental prosthesis P3 to be manufactured on the labprocessing (fixed) coping 150 with the coping 150 installed securely onthe abutment analog portion 216 of the analog and pin 212.

The prosthesis manufacturing process initially involves the installationof the lab processing coping 150 on the abutment analog portion 216 ofthe analog and pin 212, once the transfer coping 134 and its impressionI (FIG. 4) have been removed. A handling tab 152 extends from the tip ofthe lab processing coping 150, allowing the dentist to handle the copingduring intraoral procedures. The dental prosthesis P3, e.g., a singleprosthetic tooth, is then constructed on the lab processing coping 150.When this has been accomplished, the stone model with the analog and pin212, coping 150, and completed dental prosthesis P3 are returned to thedentist for installation on the abutment 116 of the insert 112 (FIG. 4)previously installed in the mouth of the patient.

FIG. 6 of the drawings provides an illustration of the completedplacement of the fixed dental prosthesis P3. The implant 112 waspreviously installed in the mouth of the patient, with the abutmentportion 116 extending above the gingival layer G. It will be noted thatthe sub-gingival flange 124, i.e., the “finish line” of the implant 112,is slightly below the surface of the gingival layer. This results in thelower, outer flange of the permanent coping 150 residing slightly belowthe gingival surface, with the lowermost edge of the prosthesis P3 alsoresiding slightly below the gingival surface due to its congruency withthe lower and outer flange of the coping 150. The result is much like anatural tooth; there is no gap between the gingival tissue and thestructure of the prosthetic tooth P3.

FIG. 7 illustrates an implant 412 and transfer coping 434 for usetherewith, with FIG. 8 illustrating the installed implant 412, and a labprocessing coping 450 and dental prosthesis P4 cemented or otherwisefixed thereon. The implant 412 of FIGS. 7 and 8 is similar to theimplant 112 of FIGS. 4 and 6, and is in fact identical thereto from thesub-gingival collar finish line 424 down, having a base 414 with helicalthreads 418 thereon and micro-threads 426 about the lower portion of theconical sub-gingival collar 424, a sharply pointed distal tip 420, andone or more axial grooves 422 formed along the base 414.

The abutment portion 416 of the implant 412 has a somewhat differentconfiguration from the corresponding abutment 116 of the implant 112 ofFIGS. 4 and 6, however. The abutment 116 is shaped for use with aforwardly positioned or anterior prosthetic tooth, e.g., an incisor,with such teeth having a somewhat thinner section in the fore-aftorientation. Thus, the non-circular, flattened shape of the abutment 116also provides for the placement of a corresponding instrument thereon torotate and thread the insert base 114 into the bone structure. However,the abutment 416 is intended for a more distal or posterior, i.e.,rearward installation in the mouth to support a molar-type tooth havinga more uniform width or thickness in both longitudinal and lateralorientations. Accordingly, the abutment 416 has a more conical shapewith a truncated top, with the circumferential groove 428 being locatedcloser to the midpoint of the conical portion. A flat 432 is formed inthe conical surface of the abutment 416, providing a non-circular crosssection at that point for an instrument to grip the abutment 416 (andthus the base portion 414 of the implant 412, formed integrallytherewith), for applying torque to advance the implant 412 through thesoft tissue and into the underlying bone. Alternatively, a tool orinstrument bit receptacle 430 having a non-circular cross section may beprovided in the upper end of the abutment 416 (or the abutments of otherimplants disclosed herein), if so desired.

The transfer coping 434 of FIG. 7 includes an abutment receptacle 436defined therein that is configured to fit closely about the abutment 416and thus the analog of the abutment. The transfer coping 434 has anexternal shape essentially identical to that of the transfer coping 134of FIG. 4, i.e., a generally cylindrical external shape, with anoutwardly extending circumferential flange 438 about the head or upperend thereof and an outwardly protruding circumferential band 440extending about the coping 434. The flange 438 and/or band 440 arepreferably non-circular, i.e., having a flat or other non-circulardiscontinuity formed thereon or therein in the manner of the flat 32formed along the side or edge of the head 30 of the abutment 16 ofFIG. 1. This prevents the impression (e.g., similar to the impression Ishown in broken lines in FIG. 4) from rotating thereon. A discontinuityor gap, respectively 438 a and 440 a for the flange 438 and band 440,may be provided to serve this function. An outwardly extending orflaring skirt or flange 444 extends circumferentially about the base ofthe transfer coping 434 from the “finish line,” i.e., the juncturebetween the base of the cylindrical body of the coping 434 and the skirtor flange 444. This skirt or flange 444 serves to expand and hold backthe gingival tissue during the fitting of the transfer coping 434 duringthe making of the impression, in a manner similar to the use of packingcord about a natural tooth that has been prepared for a fixed prostheticrestoration.

The process of forming and installing a single, fixed prosthetic tooth,e.g., the prosthetic tooth P4 of FIG. 8, is essentially the same as thatdescribed further above for the components illustrated in FIGS. 4through 6. The end result is generally as illustrated in FIG. 8 of thedrawings. The lab processing or fixed coping 450 is installed upon theabutment 416, and the dental prosthesis P4 is affixed upon the coping450, and thus upon the abutment 416 of the previously installed implant412. The lab processing coping 450 is formed in a manner similar to thecoping 150 of FIGS. 5 and 6, i.e., as a thin shell including an internalcavity or recess 458 a closely matching and mating with the contours andshape of the abutment 416 of the implant 412. The external shape andcontour 458 b has a similar shape and configuration, with the prosthetictooth P4 being formed thereover. As in the case of the installationillustrated in FIG. 6, the sub-gingival collar 424 is slightly below thesurface of the gingival layer. This results in the finish line of thefixed coping 450 residing slightly below the gingival surface, thelowermost edge of the prosthesis P4 also residing slightly below thegingival surface due to its congruency with the lower and outer flangeof the coping 450. The result is much like a natural tooth, with no gapbetween the gingival tissue and the structure of the prosthetic toothP4.

In the case of the removable prostheses shown in FIGS. 1 and 2, thedental implant system allows the prostheses to be installed and removedquickly and easily by the user thereof, while still providing secureretention in the mouth. The resilient components used in the system maybe quickly and easily replaced as needed. In the case of the fixedprostheses of FIGS. 6 and 8, the durability and security of theinstallation should provide years of use for the user, and could lastfor the life of the user. In either case, the relative simplicity ofinstallation provides many benefits both to the dental practitioner andto the patient, with those benefits providing more rapid and thus lesscostly installation.

It is to be understood that the present invention is not limited to theembodiments described above, but encompasses any and all embodimentswithin the scope of the following claims.

1-7. (canceled)
 8. A kit for a dental prosthesis, comprising: a dentalprosthesis; an implant having an abutment formed integrally therewith,the implant being adapted for implantation in a patient's mouth, theprosthesis being retained in the patient's mouth when the prosthesis isseated on the abutment; a transfer coping adapted for removableinstallation upon the abutment; a lab processing coping matching thetransfer coping, the lab processing coping being adapted forinstallation within the dental prosthesis; an analog and pin adapted forholding the lab processing coping during manufacture thereof; a sheath,the analog being slidable into the sheath for holding the analog andpin; and an elastomeric ring removably disposed about the abutment. 9.The kit for a dental prosthesis according to claim 8, further including:at least one prosthesis-retaining housing installed within the dentalprosthesis; and a rubber insert removably installed within the housing,the insert having an abutment receptacle formed therein.
 10. The kit fora dental prosthesis according to claim 9, wherein: the housing has aninwardly disposed base flange, the base flange having a plurality ofradially disposed slots defined therein; and the insert has a pluralityof axial ribs extending radially therefrom, the ribs being removablyinsertable through the slots of the base flange of the housing, the ribsbeing captured by the base flange when the insert is rotated in thehousing in order to secure the insert in the housing.
 11. The kit for adental prosthesis according to claim 10, further comprising an insertinstallation and removal instrument having an elongated shaft and a bitattached to an end of the shaft, the abutment receptacle having a slotdefined therein for receiving the bit.
 12. The kit for a dentalprosthesis according to claim 8, wherein: the implant has a tapered,helically threaded base portion having a pointed distal tip; a collaropposite the tip, the abutment extending from the collar; amicro-threaded portion disposed between the collar and the base portion;and a head disposed upon the abutment opposite the collar, the headhaving a non-circular periphery.
 13. The kit for a dental prosthesisaccording to claim 8, wherein the dental prosthesis is selected from thegroup consisting of removable partial dental prostheses and removablefull dental prostheses.
 14. The kit for a dental prosthesis according toclaim 8, wherein the dental prosthesis is a single fixed prosthetictooth.
 15. A dental implant assembly, comprising an implant having: atapered, helically threaded base portion having a pointed distal tip; acollar opposite the tip; a micro-threaded portion disposed between thecollar and the base portion; an abutment extending from the collar; anda head disposed upon the abutment opposite the collar, the head having anon-circular periphery.
 16. The dental implant assembly according toclaim 15, further including: a dental prosthesis having at least oneprosthesis-retaining housing installed therein; and a rubber insertremovably installed within the housing, the insert having an abutmentreceptacle formed therein.
 17. The dental implant assembly according toclaim 16, wherein the dental prosthesis is selected from the groupconsisting of removable partial dental prostheses and removable fulldental prostheses.
 18. The dental implant assembly according to claim16, wherein: the housing has an inwardly disposed base flange, the baseflange having a plurality of radially disposed slots defined therein;the insert has a plurality of axial ribs extending radially therefrom,the ribs being removably insertable through the slots of the base flangeof the housing, the ribs being captured by the base flange when theinsert is rotated in the housing in order to retain the insert in thehousing; and an insert installation and removal instrument having anelongated shaft and a bit attached to an end of the shaft, the abutmentreceptacle having a slot defined therein for receiving the bit.
 19. Thedental implant assembly according to claim 15, further comprising adental prosthesis consisting of a single fixed prosthetic tooth.
 20. Thedental implant assembly according to claim 19, further comprising: atransfer coping adapted for removable installation upon the abutment; alab processing coping matching the transfer coping, the lab processingcoping being adapted for installation within the dental prosthesis; ananalog adapted for holding the lab processing coping during manufacturethereof; and a sheath, the analog being slidable in the sheath forholding the analog.